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OPEN ACCESS Journal of Applied Sciences
ISSN 1812-5654DOI: 10.3923/jas.2017.212.237
Review ArticleShallow-marine Sandstone Reservoirs, DepositionalEnvironments, Stratigraphic Characteristics and Facies Model:A Review
Numair Ahmed Siddiqui, Abdul Hadi A. Rahman, Chow Weng Sum, Wan Ismail Wan Yusoff andMohammad Suhaili bin Ismail
Department of Geoscience, Faculty of Geoscience and Petroleum Engineering, Universiti Teknologi PETRONAS, Perak, Malaysia
AbstractA significant percentage of the world’s hydrocarbon reserves are found in shallow-marine sandstone deposits. Understanding the internalcharacteristics, distribution, geometry and lateral extent of these sandstones in the subsurface is therefore, an essential part of successfulexploration and production strategy. The aim of this study was to document a review on the understanding of shallow-marine sandstonereservoirs, depositional environments, stratigraphic characteristics and facies modeling which is quit challenging because of generichierarchy of different scale and sets of heterogeneities. This review was based on seven different types of clastic coastal depositionalenvironments: Deltas, tide-dominated estuaries, wave-dominated estuaries, barrier-islands and lagoons, strand plains and tidal flats. Thisstudy documented a broad examination of these depositional environments and their corresponding stratigraphic and facies modelswhich lead to a better understanding of their impact on reservoir heterogeneities within these settings. The review supports thehypotheses of previous researchers that wave, tide and river power exercise the primary control over the gross geomorphology and faciesdistribution patterns in clastic coastal depositional environments which can be applicable to any region on earth where clastic coastaldepositional environments may be identified from stratigraphic characteristics.
Key words: Shallow-marine deposits, depositional environment, stratigraphy, facies model
Received: November 21, 2016 Accepted: March 10, 2017 Published: April 15, 2017
Citation: Numair Ahmed Siddiqui, Abdul Hadi A. Rahman, Chow Weng Sum, Wan Ismail Wan Yusoff and Mohammad Suhaili bin Ismail, 2017.Shallow-marine sandstone reservoirs, depositional environments, stratigraphic characteristics and facies model: A review. J. Applied Sci., 17: 212-237.
Corresponding Author: Abdul Hadi A. Rahman, Department of Geoscience, Faculty of Geoscience and Petroleum Engineering,Universiti Teknologi PETRONAS, Perak, Malaysia Tel: +60149975114
Copyright: © 2017 Numair Ahmed Siddiqui et al. This is an open access article distributed under the terms of the creative commons attribution License,which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.
Competing Interest: The authors have declared that no competing interest exists.
Data Availability: All relevant data are within the paper and its supporting information files.
J. Applied Sci., 17 (5): 212-237, 2017
INTRODUCTION
Siliciclastic shallow-marine deposits form reservoir inmany of the world’s major hydrocarbon provinces(e.g., Brunei, Indonesia, Malaysia, Nigeria, North Sea,Venezuela, etc.). These rocks hold the vast majority of theremaining hydrocarbon reservoirs which is quit challengingbecause of generic hierarchy of different scale and sets ofheterogeneities. Identification and prediction ofheterogeneities in these reservoirs is therefore a vital toefficiently and economically produce these reservoirs1-3.Numerous studies by different groups have investigatedthe facies characteristics and their impact on reservoirheterogeneity4-10. These studies were based on outcrops andfield data and also on constructed reservoir simulation models,using detailed geological outcrop and oilfield data11-15. Amongthe objectives are to upscale and capture the effects of smallscale heterogeneities on flow performance16-25. The outcomes of this study gives a surface-based modeling approach thathas been used to construct a reservoir-scale, 3-D model of thefacies architecture, used to represent both key stratigraphichorizons and facies boundaries in the model.
Siliciclastic shallow-marine sediments and rocks areproduct of the depositional environments located betweenland and sea and their response to a variety of forcingmechanisms26. The geomorphic evolution of such depositionalenvironments (including deltas, estuaries, lagoons, strandplains and tidal flats) is controlled by the relative importanceof several main factors, which includes; physical processregime, the internal dynamics of coastal and shelf depositionalsystem, relative sea-level, sediment flux, tectonic setting andclimate. The main physical processes operating in thesesettings are river-derived flows, waves, shoreline andtidal-currents. The flow energy in such environments aregenerally higher19,27-30. This resulted in a complex pattern oftransportation and deposition of coarse sediments(silt, sand and occasionally conglomerates). The grossgeomorphology of clastic coastal depositional environmentsis affected by the relative importance of long shore currents,waves and tides in controlling the amount, nature, distributionand transportation of sediment along the coast3,10,31,32 (Fig. 1).
The significant alongshore sediment transport thatproduces coast parallel sedimentary features is by large swellwaves generate, such as spits, barriers, sand bars and barrier
Fig. 1: Significant of coast parallel sedimentary features by large swell waves generate, such as spits, barriers, sand bars andbarrier islandsTidal currents generally produce coast normal sedimentary features, including: Elongate tidal sand banks, wide-mouthed estuaries, funnel-shaped (in plainview) deltaic distributary channels and broad intertidal flats
213
Upper delta plain
Lower delta plain
Delta front
Prodelta
Tide-dominated estuary
Tidal flat
Line coast with marine sediment supply
Increasing tidal power
Tide-dominated (Retreating) River-dominated
(Prograding)
Increasing wave power
Wave-dominated estuary
Lagoon Barriers
Strand plain
Active river
Vegetated land area
Marsh Mud Sand
Wave-dominated (Retreating/prograding)
Delta
J. Applied Sci., 17 (5): 212-237, 2017
River delta
Wave delta Tide delta
Delta
Wave-dominatedestuary
Tide-dominatedestuary
Lagoon
Strand plain Tidal f lat
Fig. 2: Classification of six different types of depositional environment in ternary diagram30
islands. In contrast, large tidal ranges (>4 m) and strong tidalcurrents generally produce coast normal sedimentary features,including: Elongate tidal sand banks, wide-mouthed estuaries,funnel-shaped (in plain view) deltaic distributary channels andbroad intertidal flats (Fig. 1). These depositional settings aredominantly composed of clastic sediments and has longbeen studies all over the world18,22,28,29,33-39, mainly whichincludes, the Nile river delta, the Mississippian delta, theGanges/Brahmaputra delta and the Niger delta. Theseshallow-marine sandstone environments can be characterizedby their distinct facies which are reliable indicator of any(river, wave or tide-dominated environment) depositionalprocess (Fig. 2). Having the concept of sedimentary facies andstratigraphy, facies analyses of high quality exposures inseveral coastal plains, all over the world provide anopportunity to examine the stratigraphic nature of theseshallow-marine sandstone deposits. Based on distinctassemblages of physical and biogenic sedimentary structures,the vertical sequence of facies, each depositional environmentcan be recognized. Some present day examples have recentlybeen described by many researchers18,27,29. But the individualfacies are of little interpretative value. However, when use incombination as facies models, facies successions highlightlateral and vertical variations between different sedimentaryenvironments. A facies model represents a general summaryof a given depositional system which represent ageneralization of the physical attributes for a certain type ofdepositional environment, where the local variations fromnumerous modern and ancient examples have been ‘‘Distilledaway’’ to leave only the common features. Since, accurate
facies models are an integral part of understanding thestratigraphic evolution of a depositional system.
The aim of this study is to supports the hypotheses ofprevious researchers and reviews the documentedinformation on shallow-marine siliciclastic depositionalenvironments, the facies and stratigraphic characteristics ofthe sandstones and facies model and their impact on reservoirheterogeneity for detail analysis and demonstration onpresent conditions.
KEY CHARACTERISTICS OF SHALLOW-MARINEDEPOSITIONAL ENVIRONMENTS AND SANDSTONE
RESERVOIR HETEROGENEITY
The shallow-marine and coastal realm is defined as“The depositional system that exist between the landwardinfluence of the marine processes and the seawardinfluence of continental, mainly fluvial (river) processes40,41”.Shallow-marine environments are generally considered andclassified according to physical process regime16. The mainphysical processes operating in shallow-marine setting arewaves and storms, tidal currents and river-derived flows20.Shallow-marine sandstones can be characterized by theirdistinct features which are reliable indicators ofshallow-marine environment. First, the physical processesare generally distinctive: For example, extensive sheets andridges of cross bedded sand deposited by strong currents,hummocky and swaley cross-stratification are distinctivesedimentary structures that are believed to be unique tostorm-deposited sands. Secondly, the organisms, either as
214
J. Applied Sci., 17 (5): 212-237, 2017
body fossils, specifically benthic organisms that are onlyabundant in shelf environments or as trace fossils(distinct shallow-marine trace fossil assemblage). Third are thelithology and texture, mainly sand and mud with some graveland moderately to well-sorted.
Therefore, shallow-marine depositional system is basedupon the long-term movement of the shoreline and the keydepositional processes. This shoreline movement is controlledby the balance between the amount of sediment supplied tothe depositional system and the amount of accommodationspace created40,42. The depositional environment and faciessuccession of shallow-marine sandstone may preserveindicators of change in sea-level during transgression andregression and are often easily identified, because of theunique conditions required to deposit the different faciessuccessions (parasequences) (Fig. 1). For instance, duringtransgression the coarse-grained clastics like sand are usuallydeposited in near-shore, high-energy environments,fine-grained sediments however, such as silt and carbonatemuds are deposited farther offshore, in deep, low-energywaters43. Thus, a transgression reveals itself in the sedimentarycolumn when there is a change from near-shore facies(such as sandstone) to offshore ones (such as marl) from theoldest to the youngest rocks. A regression will feature theopposite pattern with offshore facies changing to near-shoreones43. Regressions are less well-represented in the strata,as their upper layers are often marked by an erosionalunconformity. Many studies concentrate on progradational(regression) systems because they are volumetrically mostimportant as reservoirs44,45, examples include the Niger delta46,the Palaeo-Baram delta of Borneo and Brunei18,47 and manyothers.
The shallow-marine shorelines are subdivided furtherbased upon the dominant depositional process. Six broadtypes of clastic coastal depositional environment arerecognized (Table 1), which divided into two main groups:(1) Those that receive a large sediment supply and are activelyprograding seawards (e.g., deltas, strand plains and tidal flats) and (2) Those that receive a small sediment supply and whichexhibit geomorphic features associated with the Holocene sealevel rise and have yet to completely fill their Paleo valleys48.Under conditions of stable sea level, the existence of thesetypes of clastic coastal depositional environments depends onthe relative quantities of terrestrial and/or marine sedimentsupplied in relation to the size of the receiving basin. Becauseof the close link between the geomorphology of clastic coastaldepositional environments and the relative influence of wavesand tides at the coast, it is possible to distinguish betweenwave-dominated coasts (characterized by wave-dominated
deltas, wave-dominated estuaries, strand plains and lagoons)and tide-dominated coasts (characterized by tide-dominateddeltas, tide-dominated estuaries and prograding tidal flats(Fig. 1). All shallow-marine depositional systems are affectedto a greater or lesser degree by all of these six depositionalprocesses classified within a ternary diagram scheme (Fig. 2).Any point within the triangle is defined by the relativeimportance of depositional environment in controlling theresultant facies (and ultimately, reservoir) architecture forbuilding model.
DELTAS
Deltas are formed from the deposition of the sedimentcarried by the river as the flow leaves the mouth of theriver22,45,49,50. Over-long period of time this deposition buildsthe characteristics geographic pattern in the form of thetriangular shape of the fourth letter of the Greek alphabet ()).As the sediment-laden, river enters the standing body ofwater, the flow decelerates, which diminishes the ability of theflow to transport sediment. As a result, sediments drop-out ofthe flow and deposits. Over time, this single river channel willbuild a deltaic lobe (such as, the birds-foot of the Mississippidelta, the Nile delta shown in Fig. 3), pushing its mouth furtherinto the standing water. As the river enters the standing waterof sea the morphologies of delta changes, the original deltaicshape range from elongate ‘finger’ building out into the sea(such as the Mississippi delta), to highly prominent sand barsand ridges parallel to river direction (tidal delta) or to highlyreworked distributary channels and mouth-bars of river bywaves, which form a beach ridge barriers complex thatapproximately parallel to the shoreline. In this regard, thereare three key processes have been identified in delta system,i.e., fluvial, wave and tide-dominated delta system40,51,52 (Fig. 2).
Depositional environment and process: The formation ofdelta system consist of three main forms; the delta plain(where river process dominate), the delta front (where riverand basinal processes are both important) and the prodelta(where basinal processes dominated)53 (Fig. 4) from subaerialdelta setting to subaqueous delta. This form, from delta plainto prodelta may be influence by tide or wave-dominatedprocesses which change the morphology of depositionalenvironment with subaerial to subaqueous delta. Within thisforms the basic depositional environment in a deltaic systemis the mouth-bars41,54, as, if the sediment is not significantlyreworked by the wave and tidal-dominated processes. Themouth-bars, which as aggrades, it eventually becomesemergent and diverges the river into two distributary channels
215
J. Applied Sci., 17 (5): 212-237, 2017
216
Table 1: Sum
mary of
differ
ent d
epos
ition
al env
ironm
ents, s
tratigraph
ic cha
racter
istics a
nd fa
cies
mod
el w
ith m
oder
n, anc
ient
and
oil fie
ld exa
mples
Shallow-m
arine
enviro
nmen
tsDist
inct env
ironm
ents and
facies
Repr
esen
tativ
e stratig
raph
yMod
elEx
amples
Deltas
Dist
ribut
ary ch
anne
ls (coa
rse-
to fine
-grained
),Mod
ern:
Nile
and
Miss
issippi delta
19,44,35
mou
th-b
ars,
distal m
outh
-bars
Ancien
t:Ba
ttfje
llet a
nd Pen
nsylva
nian
Per
rin delta
35
(mud
ston
e an
d sil
tsto
ne)
Oil-fie
lds:
Nun
field Niger
ia and
Gud
ao oil fie
ld China
81
Sour
ce: U
GA
Stratig
raph
ic la
bW
ave-
dom
inated
Wav
e rip
ples
and
hum
moc
ky cro
ss-stratifica
tion,
Mod
ern:
Nile
delta and
Brazo
s delta
28
delta
sso
ft se
dim
ent d
efor
mation, clim
bing
cur
rent
Ancien
t:Niger
and
Baram
delta
18,58
ripples
, brack
ish fa
una an
d stak
edOil-fie
lds
Niger
ia delta and
Bud
are fie
ld,
coarse
ning
and
fining
-upw
ard facies
Easter
n Ve
nezu
ela5
8
Sour
ce: W
alke
r and
Jam
es53
Sour
ce: N
icho
ls74
Tide
-dom
inated
Strata disp
lays
coa
rsen
ing-
up of a
delta w
ith tida
lMod
ern:
Gan
ges-Br
ahm
aput
ra and
delta
sch
anne
ls of
delta plain and
tida
l flat o
f delta to
pCh
angjiang
tida
l delta
73
facies
, struc
ture
includ
es, c
ross bed
ding
, tidal
Ancien
t:Ch
angjan
g tid
al delta and
bedd
ing, re
activ
e su
rface
and
flas
er, w
avy an
dFly riv
e tid
al delta
58,73
lent
icular bed
ding
, her
ringb
one cros
s-stratif
ication,
Oil-fie
lds
Troll W
est f
ield, N
orweg
ian Nor
th se
am
ud drape
s and
cha
nnel ero
siona
l bas
ean
d La
gunilla
s field W
este
rn Ven
ezue
la73
Sour
ce: U
GA
Stratig
raph
ic la
bSo
urce
: Nicho
ls74
Tide
-dom
inated
Floo
d plain (b
urro
ws a
nd m
udston
e), tidal flat
Mod
ern:
Fitzro
y an
d Am
azon
rive
r66
estu
aries
(trou
gh cro
ss, flase
r and
lent
icular bed
ding
)An
cien
t:Ch
angjan
g es
tuary an
d Giro
nde es
tuary7
3
and tid
al cha
nnels a
nd point
bar w
ith ero
sive ba
seOil-fie
lds:
Sach
a fie
ld Ecu
ador
and
Asp
elinto
ppen
Form
ation Ce
ntral B
asin of S
pitsbe
rgen
65
Sour
ce: U
GA
Stratig
raph
ic la
bW
ave-
dom
inated
Upp
er sh
orefac
e (tr
ough
cro
ss sa
ndston
e),
Mod
ern:
Dan
ube an
d Ba
ram
estua
ry18
,77
estu
aries
lower
shor
efac
e (p
roxim
al st
orm
bed
with
Ancien
t:Hue
co fo
rmation So
uth-
Cent
ral N
ew M
exico
mud
ston
e inte
rbed
ded)
and
offs
hore
and Flor
as la
kes S
outh
-Wes
t Ore
gon1
9
(bur
rowed
mud
ston
e with
stor
m bed
)Oil-fie
lds:
Little Bow
field, Can
ada an
d Finn
mark fie
ld,
Nor
th N
orway
37
Sour
ce: U
GA
Stratig
raph
ic la
b
J. Applied Sci., 17 (5): 212-237, 2017
217
Table 1: Con
tinue
Shallow-m
arine
enviro
nmen
tsDist
inct env
ironm
ents and
facies
Repr
esen
tativ
e stratig
raph
yMod
elEx
amples
Barrier isla
ndBa
rrier isla
nds a
re m
ainly sa
nd and
grave
lMod
ern:
Albe
marle and
Pam
lico Fe
rron
bea
chan
d lago
ons
(sub
horiz
ontal (plan
ar) s
tratifica
tion an
d wav
elago
on in
Nor
th Carolina8
3
rewor
king
stru
ctur
e) and
lago
on con
sist o
f bot
hAn
cien
t:Fe
rron
San
dsto
ne U
tah an
dm
ud and
sand
(int
erbe
dded
and
inte
r-fin
gerin
gVe
nice
lago
on Italy1
3
sand
ston
e, sh
ale, silts
tone
and co
al)
Oil-fie
lds:
Sabk
ha fie
ld an
d Tigre lago
on oil f
ield, L
ouisian
a78
Strand
plains
Beac
h rid
ges (
sand
and
grave
l with
in fine
or
Mod
ern:
Wes
tern
Lou
isian
a an
d strand
plain, B
ahia
coarse
ning
coa
stal plain or u
pward-
fining
Prov
ince
, Brazil (So
urce
: Wikiped
ia)
chan
nel s
ands
tone
s and
che
nier
s plains
Ancien
t:Sa
n Ju
an bas
in out
crop
, Frio
form
ation Te
xas
of fine
-grained
sedim
ent
at A
ustin
87
Oil-fie
lds:
Fario
form
ation fie
ld Te
xas a
nd se
vent
y six W
est
field, S
outh
Tex
as86
,87
Tida
l flats
Burrow
ed tr
ough
cro
ss-la
minated
sand
ston
eMod
ern:
Abu Dha
bi Per
sian Gulf a
nd O
ban on
Ste
wart
with
false
r to lent
icular bed
ding
and
hav
ing
islan
d, N
ew Zea
land
(Sou
rce: W
ikiped
ia)
fining up
ward tren
dAn
cien
t:Pa
lmares
form
ations
, Nor
th-Eas
tern
Brazil a
ndSa
bkha
s out
crop
Utah2
7
Oil-fie
lds:
Sam
-Bis
oil field N
iger
ia94
Sour
ce: U
GA
Stratig
raph
ic la
b
J. Applied Sci., 17 (5): 212-237, 2017
Fig. 3(a-b): Google and satellite images of (a) Mississippi delta and (b) Nile delta, an example of river dominated deltas, shows thedistribution of single channel into distributary lobes
Fig. 4: Three main forms of delta; the delta plain (where river process dominate), the delta front (where river and basinal processesare both important) and the prodelta (where basinal processes dominated)53
on either side of the bar. Two small mouth-bars are thendeposited in the mouths of these channels and the channelcontinues to split until become too small to carry sediments(Fig. 5). After this, the system becomes chocked and avulsionor lobe switching occurs35, the good example is Mississippidelta system.
The formation of shallow-marine deltaic basins is typicallyexhibit a lobe shape with multi-scale coeval terminaldistributary channels35. The relationship of terminaldistributary channels and coeval mouth-bars has been
described by Olariu and Bhattacharya35, Van Heerden55 andDuMars56. Recent studies28,35,54,57 showed that both modernand ancient delta-front have a complicated morphology,consisting of multiple terminal distributary channels,subaqueous levee deposits and mouth-bars. Few studies havebeen dedicated to delta-front deposits, despite the keyimportance of delta sub-environment to understanding deltagrowth and facies architecture35. Hence, distributary channelsare described from delta plain and from when the mainchannel reaches an area with low variability of lateral gradient
218
(a) (b)
J. Applied Sci., 17 (5): 212-237, 2017
Fig. 5: Conceptional formation and evolution of a terminal distributary channel mouth-bar system54
Three main phases of evolution have been distinguished, (i) Formation of new terminal distributary channels and mouth-bars, (ii) Migration of mouth-barsand extension of terminal distributary channels and (iii) Abandonment of terminal distributary channels. Dotted lines represent subaqueous features
into shallow-water environment. Because the delta plaingradient are small and sedimentary rates are higher, thedirection of distributary channels can be change easily byaggradation of different facies architecture or differentialsubsidence and compaction, such that the gradient will besteeper in other direction and might capture part of the flow,creating a new distributary channels.
As a consequence of this successive splitting, thedistributary channels become smaller in the downstreamdirection. Olariu and Bhattacharya35 indicated that with eachbifurcation or avulsion of channel width and depth changes asBk+1 = 0.7Bk and hk+1 = 0.8hk, respectively. Where, ‘B’ is channelwidth, ‘h’ is channel depth and ‘k’ is channel order. For a largedelta system (Volga delta, Lena delta), distributaries canrejoin, forming a delta pattern similar to braided oranastomosed rivers35. This results in smoothing of the platform(or map-view) shape of the delta as the channels move acrossits surface and deposit sediment. Because, the sediment is laiddown in this fashion, the shape of these deltas approximatesa fan. In case of wave delta system where waves redistributethe sand supplied to the beach by the rivers, the delta shapechanges, known as wave-dominated delta. The sediment is
carried off down the longshore drift direction and mouth-barsof distributary channels are unstable and easily reworked bywaves, which form a beach-ridges barriers complex that isapproximately parallel to shoreline. The modern example isthe Nile delta in Egypt19, the Sao Francisco in Brazil, Baram inBorneo and Ebro in Spain.
Whereas, if the delta is influenced by the tidal energy, thegeomorphology of the delta changes to tide-dominated delta,with features a landward tapering funnel-shaped valley(Fig. 1) and river is connected to the sea via distributarychannels58,59.
Stratigraphy: The deltas are characterized by multiplelaterally discontinuous sand bodies arranged in complexspatial patterns. This complexity reflects the hierarchicalstaking of lobate depositional bodies that form bydeceleration of effluent water at the mouth of deltaicdistributary channels debouching into a standing body ofwater60. Such depositional bodies have been documented atfour distinct orders of a stratigraphic hierarchy in deltas:(1) Distributary mouth-bars, which correspond to theindividual mouth-bar in river delta and associated delta front
219
Subaqueous levee Channel
thalweg split Subaqueous mouth-bar
Emergent mouth-bar
New terminal distributary
channel Terminal distributary
channel
Phase I
Phase II New channel split Sub-mouth bars
Phase III
Channel infill (abandonment)
J. Applied Sci., 17 (5): 212-237, 2017
Fig. 6: Arrangement stratigraphic elements in delta distribution and its control of variety of autogenic and allogenic processesresulting in complex stratigraphic architecture74
and prodelta deposits fed via terminal distributary channels49,(2) Mouth-bars assemblages, which comprise multiplecoalesced mouth-bar deposits that is fed via the same shallowdownstream-bifurcating distributary channel network withparallel mouth-bars (in wave-influence processes) to shorelineor perpendicular mouth-bar (in tidal-influence processes) toshoreline, (3) Delta lobes, each of which have bed feed viasingle major trunk distributary channel35 and corresponds toa delta front clinoform set59 and (4) Delta complex, whichcomprise multiple delta lobe that formed via switchingbecause a nodal avulsion of major trunk distributary andwhich correspond to laterally offset and compensationallystacked clinoform sets61.
It has been studied that, the deposits of an abandonedlobe will gradually compact as water deposited with thefine-grained sediment escapes from the pore spaces and thebulk density increases. This compaction occurs without anyadditional load and results in the abandoned lobe subsidingbelow sea level. The beds that mark the end of sedimentationon a delta lobe are known as the abandonment facies41. In theupper part of the delta plain there will be peats or paleosols,which represents a low elastic supply to this part of the plain,after this, that active lobe progradation have been movedelsewhere on the delta. These fringes of the delta lobe will beareas of slow, fine-grained deposition of shallow water.Abandonment facies may show intense bioturbation becauseof the slow sedimentation rate. The arrangement of thesestratigraphic elements was controlled by a variety ofautogenic and allogenic processes resulting in afundamentally complex stratigraphic architecture49 (Fig. 6).
Facies characteristics: A common feature of deltas is channelinstability due to very low gradient of the delta plain, resultingin frequent avulsion of the major and minor channels calleddistributary channels, leaving the formal channel, its leveesand overbank deposits abandoned. The deposition of deltashave well-developed delta top facies, consisting of channeland overbank sediments. The characteristics of these facies,the overbank areas of a delta top and plain may be sites ofprolific growth of vegetation, leading to the formation of peatand eventually coal. The channels build out to form the ‘toes’of the ‘bird’s foot’, with upward thickening and coarseningdelta front deposits have terminal-distributary channels faciesinterbedded with mouth-bar deposits (Fig. 7). In general,mouth-bar has different sedimentary structures compared toterminal distributary channels35. The mouth-bar having theinterbedded upward-coarsening or thickening succession ofburrowed, ripple cross-laminated, graded bedding, planarparallel, massive and trough cross-stratification sandstonescontain disseminated organic matter and thin organic-richmudstone (Fig. 7). Whereas, terminal distributary channels,usually having poorly sorted, medium to coarse-grained,unidirectional trough cross-stratification sandstone containingoccasional mud clasts, flute casts and plant fragments. Thepreserved organic matter is commonly high in delta fronts53.
In river-dominated deltas, prodelta mudstones andsiltstones are typically massive to well-stratify and may showgraded bedding. The graded bedding may results from(1) The setting of material carried out in suspension as abuoyant plume or (2) From density underflow generated atthe river mouth during time of high discharge50. The amount
220
Delta plain
Delta channel Mouth-bar
Prodelta
Deep sea
Interdistributary bay
Abundant delta lobes Current delta lobe
Delta front
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Fig. 7: Facie characteristics and stratigraphic distribution of delta depositional environment shows the different sets ofparasequences and sedimentary structures from prodelta to delta plains
of bioturbation in variable, depending on rate of sedimentsupplied, wave-formed structure are common. Soft-sedimentdeformation features resulting from high sedimentation rates,are common in prodelta, or any be on a very large scale andinvolve large proportions of the delta front sediments, as inthe Mississippi62.
TIDE-DOMINATED ESTUARIES
An estuary is a partly enclosed coastal body of water withone or more rivers or streams flowing into it and with a freeconnection to the open sea63-66. The physical and biologicalprocesses in nearly all estuaries are influenced by tides. Thedegree of influence is governed by estuarine morphology,tidal range, water and sediment discharge, wind and shelfprocesses. Tide-dominated estuaries are those in which tidalcurrents play the dominated role in the opposition of riversediment supply63. There is appreciable upstream transport ofbedload sediment as a result of deformation of tide duringpropagation.
Depositional environment and processes: Amongtidally-influenced sedimentary environments, tidal estuariesare perhaps the most variable and difficult to characterize. This
variability is due in part to the major role that fluvial systemdominantly plays in defining estuary. A tidal estuary is apartially enclosed body of water formed where freshwaterfrom river and streams flows into the ocean, mixing with thesea water under the influence of micro to mega tidalcurrents64-67. The tidal estuary are typically flanked bylow-laying vegetated flood plains, tidal flats and swamps areabecause of appreciable tidal ranges and low incident wavepower, results in coast parallel tidal bars with drainagechannels (Fig. 8). Because of the dominance of tidal processes,the geomorphology of tide-dominated estuary features alandward tapering funnel-shaped valley and the river isconnected to the sea via distributary channels, channels maybe separated by a large expanses of low gradient vegetatedswamps59 (Fig. 8).
Most of the tidal estuaries today are located in tectonicallyactive, low latitude region, including South Asia, East Asia andOceania (Fig. 9). Many processes relevant to the developmentof tidal estuary system are common to these areas. First isamplification, in high tidal range, area is supported by broad,relatively shallow continental shelves and seas that are wellconnected to open ocean, e.g., Amazon estuary in Brazil,river Nith Estuary in South West Scotland and Exe Estuary inEngland are good examples. A second factor is common to
221
Mudstone Sandstone
Silty sand
Coal
Delta plain Proximal delta front (Terminal distributary channels) Proximal delta front (Mouth-bars) Distal delta front (Distal mouth-bars) Prodelta
20
10
15
10
0 m
Facies Environment
M S vf f m c
Sand
Lithology Structures
Parallel lamination Bioturbation Cross bedded trough Herring-bone cross bedded Flaser bedded Hummockey cross-stratified Wave-ripple lamination
Erosive Mud clasts
Coal Poorly sorted, medium to coarse-grained, unidirectional trough cross-stratified sandstone containing occasional mud clasts, flute caste and plant fragment Interbedded, upward-coarsening, thickening-upward succession of planar-parallel, massive and trough cross-stratified sandstone containing disseminated organic matter and thin organic-rich mudstones. Intensely burrowed, very-fine-grained sandstone and silty sandstone with relict hummocky cross-stratification, organic rich beds are few centimeters thick are common Dark to black mudstone containing occasional thin silty sandstone
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Fig. 8: Geomorphology of tide-dominated estuary features a landward tapering funnel-shaped valleyIt shows a typically flanked by low-laying vegetated flood plains, tidal flats and swamps areas because of appreciable tidal ranges and low incident wave power,results in coast parallel tidal bars with drainage channels during flood and ebb tides
Fig. 9: Map of world’s major river deltas systemWith those forming tide-dominated deltas indicated in black circles are mostly located in tectonically active, low latitude region
most tidal estuaries and in many delta systems in general isthat, they drain high-standing, tectonically active mountain68.Such active orogeny yield the abundant sediment required forestuary/delta to form in high-energy coastal basins. Inparticular the Himalayan-Tibetan uplift and IndonesiaArchipelago Sustain among the world’s highest sedimentyield68.
Stratigraphy: The tidal estuaries are initially formed at thebeginning of transgression and migrate landward astransgression proceeds. As far as is known, relatively littlemorphological changes occurs during this process, as longas the external process variables remain constant and thefacies zones simply translate landward63. Morphologicalchanges which cause deviations from the end-member
222
Marine
Tidal process
Tide
River
Ebb tide
Flood tide
Tidal sand bars
Incised valley
Tidal cracks Tidal channel
Vegetation area
Swamp
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Fig. 10(a-c): Cyclical stratigraphic model of tidal estuary(a) Formation of incised valley with fluvialdischarge which allows the deposition of channelsequence, (b) Tidal estuarine flank deposits overthe channel sand with bay line transgressedtowards the landward side and (c) Building oftidal inlet, bars and tidal ravinement surface
model begin to occur, however, once the rate of sedimentsupply exceeds the rate of relative sea-level rise and theestuary starts to fill.
With the advance of sequence stratigraphy in the late1980s, several geologically models results that anincised-valley system with a basal sequence boundary is filledwith transgressive deposits42. Here the cyclical stratigraphicmodel shows, estuaries valley fill is typically overlain directlyby open marine shelf deposits with an intervening transitional
phases48,69,70. The phase one (Fig. 10a) the fluvial dischargeallow the deposition of channel sequence with formation ofincised-valley. As the tidal-influence dominated over the riverdischarge, the tidal estuarine flank deposits over the channelsand with bay line transgressed towards the landward side(Fig. 10b). Finally, the tidal estuarine model builds with tidalinlet, bars and tidal ravinement surface (Fig. 10c). This is done,because of in tide-dominated estuaries, tidal current readilyredistribute the sediment supplied by both river and marinesources48. As a result, there is rapid in filling of the deeper andwider parts and development of the classic funnel-shapedgeometry and facies distribution. Once this situation exists,further sediment input should cause the stratigraphic zones toprograde seaward, with the relative distribution of faciesremaining essentially constant. The stages in the growth of thetidal sand bars have been discussed by Harris71, who showedthat the bars become broader as the estuary fills.
Facies characteristics: The tide-dominated estuary facies arepoorly known from the stratigraphic record and arenotoriously complex, owing to the wide spectrum of faciesencountered and their spatial/temporal variability72. As thetotal-tidal energy is not as pronounced as in wave-dominatedestuaries, because tidal energy penetrates further headwordthan wave energy. Thus, the facies distribution is not asobvious and sands occur in the tidal channels that run alongthe length of the estuary63. The muddy sediments accumulateprimarily in tidal flats swampy and marshes, deposited alongthe side of the estuary. Hence, tidal estuary fill depositsshowing an upward fining succession with three basicdeposition facies; subtidal flat, intertidal flat and supratidal flat(Fig. 11).
The estuary sequence is a complex of intertidal andshallow subtidal, mostly channel form intra-coastal faciesdominated to some extent by tidal processes, exhibitingconspicuous variation in sedimentary texture, compositionand provenance and in physical biological sedimentarystructures40,48. The depositional environment comprising thiscomplex of facies may encompass any number (or all) of thefollowing: Tidal deltas, inlets, shoals, back-barrier, beaches,washover fans, swamps, point bars, tidal flat, marshes andchannels. Thus, deposition of estuaries can be recognized asdistinct entities but consisting of numerous component facies.Good example of vertical facies variability within a singlesystem is shown in Fig. 11, which showed the characteristicsbed forms include tidal bars, tidal flat, channel, swamps andflood plains, with characteristics sedimentary structures ofcross bedding, flaser to lenticular bedding, swamp burrowedand bedding structures.
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Fluvial deposits
Incised valley
Sequence boundary (Channel horizon)
Estuarine flank deposits
Interfluves
Fluvial deposits
Bay line
Small point bars
Transgressive bay flooding surface
Flood tide
Transgressive estuary
Tidal ravinement surface
Tidal inlet
(a)
(b)
(c)
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Fig. 11: Tidal estuary fill deposits showing an upward fining succession with three basic deposition facies and differentsedimentary structures of subtidal flat, intertidal flat and supratidal flat42
Changjiang estuary is one of the good example of tidalestuary, located in Southern Jangsu province of NorthernZhejiang province of China. Estuary deposits show an upwardfining succession were classified into five facies73: Tidal river,channel, muddy intertidal to subtidal facies, transgressive lagand tidal front. They consisted mainly of tide-influencedsediments such as very thinly interbedded to thinly laminatedsand and mud (sand-mud couples), indicating that the estuaryis a tide-dominated type. Moreover, most of the sediment forthe estuarine fill would be supplied by the Paleo-Changjiangriver, resulting in a significant difference in the morphologicalcomponent with an idealized tide-dominated estuaryillustrated by Dalrymple et al.63, whose model cannot beapplied to a large-river estuary, the Paleo-Changjiang73.
WAVE-DOMINATED ESTUARY
In typical wave-dominated estuary, tidal influence is smalland the mouth of the system experiences relatively high waveenergy. The waves redistribute the sand supplied to the beachby the rivers. The sediment is carried off down the long shore
drift direction and mouth-bars of distributary channels areunstable and easily reworked by waves, which forms a beachridge barriers complex that is approximately parallel to theshoreline19 (Fig. 12).
Depositional environment and processes: Inwave-dominated estuaries, the main conduits of sedimentinput to the estuarine environment are the marine inletchannel and the bay head delta channel(s). Sediment broughtinto an estuary by the routes is subject to different transportprocesses based upon their particle size in relation to thecurrent velocity. Generally, coarse sediment is transported asbedload, whereas, finer sediment is carried in suspension.Bedload is generally deposited on the marine tidal delta orfluvial delta complexes during either the ebb and flood flowsof the tidal cycle (Fig. 12) or during periods of river flow,respectively63. Exceptions may occur during flooding events,when bed load sediment may be transported beyond the limitof the bay head deltas. Sediment in suspension is transportedfurther than bedload and usually accumulates in thelow-energy central basin of wave-dominated estuaries.
224
Lithology Structures Facies Environment
Swamp Coal
Burrowed and rooted mudstone
Burrowed mudstone and trough cross-laminated sandstone with flaser to lenticular bedding Sigmoidal cross bedding sandstone and erosive base channel
Supratidal flat Flood plain Intertidal flat Tidal flat Tidal point bar Subtidal flat Tidal channel
Flooding surface
Parallel lamination
Bioturbation
Cross-bedded trough
Herring-bone cross-bedded
Flaser bedded
Hummockey cross-stratified
Wave-ripple lamination
Erosive
Mud clasts
Mudstone
Sandstone
Silty sand
Coal
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Fig. 12: Typical wave-dominated estuary and other geomorphic featuresIn this delta tidal influence is small and the mouth of the system experiences relatively high wave energy, which forms a beach ridge barriers complex thatis approximately parallel to the shoreline. The bed loads is generally deposited on the marine tidal delta or fluvial delta complexes during either the ebband flood flows of the tidal cycle
Suspended sediment usually undergoes repeated cycles oferosion, transport and deposited by ebb and flow tidalcurrents74, before reaching this location (deposition occurringduring the slack water period between ebb and flow tides).
In wave-dominated estuaries, coarser sediments have atendency to become concentrated at the shore and finesediments are shifted offshore75. The sediment which isconcentrated at the shoreline of any estuary may be reworked(e.g., by winnowing) or re-suspended by wave action if it ispresent wind where prevalent, may introduced coastal sandsinto their shoreline deposits. Roy et al.76 considered the marinetidal delta zone of wave-dominated estuaries to consist ofhigh and low energy sub-environment with the formerincluding deep tidal channels and shoaling bay beds and thelatter including shallow subtidal and intertidal sandflats/shoals occurring along channel margins and the muddy slope-zone in the delta front (Fig. 12). The variability (spatial and temporal) of different flow types, leadsto a complex distribution of estuarine sediments andtherefore, sedimentary environments. Hence, a great range ofsuch environments exist within estuaries due to variation tobe found in these milieus19.
Stratigraphy: A typical wave-dominated estuary composedas like tidal estuary. By Allen and Posamentier69 a
wave-dominated estuary is composed of following systemtracts from bottom to top (Fig. 13): (1) Low-stand System Tract(LST), composed of fluvial sand and gravels, overlaying theSequence Boundary (SB) formed during sea-level low standby subaerial exposure and wave-erosion, (2) TransgressiveSystem Tract (TST) separated from the LST by thetransgressive surface and formed by estuarine sands andmuds, where some or all of the barrier-bar complex is likely tobe eroded during shoreface retreat and (3) High-stand SystemTract (HST) constituted by a seaward prograding wedgecomposed of estuarine point bars, tidal bars and tidal flatsdown lapping onto a Maximum Flooding Surface (MFS) thatoverlies the estuary mouth sands and control basin muds.Whereas, the bay-head depositional facies system are likely tobe common at the base of transgressive successions and canoccur at the head of the progradational estuary, where theywith exhibit an upward-coarsening succession.
Facies characteristics: Wave-dominated estuary depositsdisplay well-developed mouth-bars and beaches sediments,occurring as elongated coarse sediment bodies approximatelyperpendicular to the orientation of the delta river channel.The estuary front facies is usually characterized by a relativelycontinuous coarsening upward facies succession, as inwave-dominated delta system. The proportion of
225
Littoral wave drif
Beach barrier
Central basin lagoonal type
Ebb tide delta
Flood tide delta
Mangroves
Intertidal flats
Vegetation area Salt marsh Fluvial
delta
Tidal limit
Fluvial discharge (Bay head)
Flood plain
Inlet tidal flats
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Fig. 13: Wave-dominated estuary and its composition of system tracts, High-strand System Tracts (HST) with mostly of sand andmudstone, Transgressive System Tracts (TST), with mudstone and Low-strand System Tract (LST) with mostly of sandstone
wave-produced structures (such as wave ripples) tends to begreater, whereas, indicators of high sedimentation rates andfresh water influence (e.g., soft sediment deformation,climbing current ripples, brackish fauna and syneresis cracks)tends to be fewer. The inter-distributary and inter-lobe areastends to be less sandy and commonly contain a series ofrelatively thin succession, staked coarsening andfining-upward facies28.
An estuary developed in an area with a small tidal rangesand strong wave energy has typically three division; thebay-head, the central basin (lagoon) and beach barrier. Thebay-head facies deposited at the zone where fluvial processesare dominate or river flow enters the central lagoon. It formcoarsening-up, progradational succession with channel andoverbank facies building out over sands deposited at thechannel mouth, which in turn overlies fine-grained deposits ofcentral lagoon63 (Fig. 14). In central lagoon, where waveenergy is mainly concentrated at the barrier bar is the regionof fine-grained deposition with organic rich marsh vegetationor mangroves. When central lagoon becomes filled withsediment, it becomes a region of salt-water marshed crossedby channels. In many estuaries, the central lagoon thatreceives influence of sand may be area where wave-ripplesform washover of barrier island during high wave energy28.
The outer part of wave-dominated estuary deposits thebeach barrier which has the same characteristics as thosefound along clastic coasts, but it is elongated body which isparallel to shoreline and encloses fine-grained deposits ofcentral lagoon. The good example of wave-dominatedestuary is Danube estuary, formed by an alternate channelextension process50. The delta shows remarkablemorphological variability as a result of variation in bothriverine discharges among distributaries as well as waveenergy along coast. During delta evolution, both river andwave-influenced lobes have been associated with different
distributary77. Successive bifurcations of the terminaldistributary channels via middle ground bar formation at themouth, resulting in the development of a classical lobateriver-dominated delta28. Minor wave reworking, periodicallyresults in small barrier bars and splits at the mouths ofsecondary distributaries. The main sedimentary facies of theDanube estuary are channel, lagoonal complex located in theSouthern most part of the delta and some secondary channels.Some marsh deposits mostly of organic origin are formed indepression areas with marsh vegetation28.
BARRIERS ISLANDS AND LAGOONS
The barrier islands is the coastal landform and a type ofbarrier system that is relatively narrow strip of sand, parallel tothe mainland coast. Whereas, main coasts forms a lagoon in ashallow body of water separated from large body of water bybarrier islands. They usually occur in chains, consisting ofanything from a few islands to more than a dozen, exceptingthe tidal inlets that separate the islands. A barrier chain mayextend uninterrupted for over a 100 km, the longest andwidest being Padre island in Mexico Gulf78.
Depositional environment and processesBarriers: Along some coastlines a barrier of sedimentseparates the open sea from a lagoon that lies between thebarrier and the coastal plain (Fig. 15). They may be partiallyattached to land, that completely encloses a lagoon or can beisolated as a barrier island in front of a lagoon. The conditionsrequired for a barrier to form are as followed by Boggs79: First,an abundant supply of sand or gravel-sized sediment isrequired and this must be sufficient to match or exceed anylosses of sediment by erosion. The supply of the sediment iscommonly by wave-driven long shore drift from the mouth ofa river at some other point along the coast and there may also
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Fluvial gravel and sands (LST)
Tidal inlet sands
Estuarine sand and muds
Marine sands
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Fig. 14: Stratigraphic succession of wave-dominated estuary with progradational succession having channel and overbankfacies building out over sands deposited at the channel mouth, which in turn overlies fine-grained deposits of centrallagoon42
Fig. 15: Distribution of depositional setting of barrier and lagoon system
227
Coastal plain Flood tide
Barriers Ebb tide
Sea Lagoon
Longshore drift
Wave front
Mudstone
Sandstone
Silty sand
Coal
Facies Environment Parallel lamination Bioturbation Cross bedded trough Herring-bone cross bedded Flaser bedded Hummockey cross-stratified Wave-ripple lamination Erosive Mud clasts
Structures
Beach Estuary mouth Central logoon Bay head
Trough cross bedding, cross lamination
Interbedded sand and clay with ripple cross stratification Burrowed mudstone and sandstone with flaser to lenticular bedding Sigmodial cross bedding sandstone and erosive base channel
Lithology
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be some reworking of material from the sea bed furtheroffshore78. Second, the tidal range must be small. Inmacro-tidal setting the exchange of water between a lagoonand the sea during each tidal cycle would prevent theformation of a barrier, because a restricted inlet would not beable to let the water pass through at a high enough rates79.Therefore, barrier island systems are best developed inmicro-tidal and some extent to meso-tidal settings. The thirdprocess to form barrier is generally under condition of relativesea-level rise condition75,80,81. If there is a well developed beachridge, the coastal plain behind it may be lower than the top ofthe ridge, hence with a small sea-level rise, the coastal plaincan become partially flooded to form a lagoon and beachridge will remain subaerial, forming a barrier.
Lagoons: Lagoons are coastal bodies of water that have verylimited connection to open ocean. Sea water reaches a lagoondirectly through a channel to the sea or via seepage throughbarrier, fresh water is supplied by rainfall or by surface run-offfrom the adjacent coastal plain41. Lagoons generallydeveloped along coasts where there is a wave-formed barrierand are largely protected from power of open ocean wave.Tidal effects are generally small because the barrier lagoonmorphology is only well developed along coasts with a smalltidal range. The fine-grained clastic sediment is supplied tolagoons as suspended material in seawater entering past thebarrier and in overland flow from the adjacent coastal plain82.Organic material may be abundant from vegetation whichgrows on the shores of the lagoon. Some coarse-grained maydeposited in lagoon when storm wash the sediment over thebarrier, which form thin layer of sand reworked by waves.Lagoonal process can be identified by fossil assemblage bymarine influence and associated facies, i.e., lagoonal depositoccur above or below barrier sediments82,83.
Stratigraphy: Barriers are developed in the part of thewave-dominated system where wave action reworks marinesediment. The stratigraphic facies characteristics of the barrierare the same as those found along clastic coast84. An inletallows the exchange of water between the sea and the centrallagoon and if there is any tidal current, a flood tidal delta ofmarine-derived sediment may progrades into central lagoon,which form under the barrier succession. As river flow rapidlydecreases and the wave energy is mainly concentrated at thebarrier bars, the lagoons are formed75. The lagoon is thereforeform a fine-grained deposition succession, often rich inorganic material. The relative thickness of each is dependingon the balance between fluvial and marine supply of sedimentduring transgression and regression. The concept ofregression and transgression refer to the overlapping of
deeper water sediment over landward deposits in lagoon(transgression) or migration of shoreline oceanward to formbarrier (regression).
Facies characteristics: The facies of barrier islands are mainlysand and gravel, whereas the lagoonal (back barrier) depositsconsist of both mud and sand. The transition between lagoondeposits and barrier deposits occurs in the over lappingsub-environments of the back barrier tidal flats, marsh,washover fans and flood tidal deltas81,84. The barrier depositsdominate sedimentary structures of subhorizontal (planar)stratification and wave reworking with mostly sand and gravel(Fig. 15). Whereas, lagoon sequence consist of interbeddedand inter-fingering sandstone, shale, siltstone and coalfacies characteristics with number of overlappingsub-environment74,85 (Fig. 15). Sediment accumulation rateand relative sea-level rise in lagoons. Sand facies includeswashover sheet deposits and channel fill deposits of floodtidal delta origin. Fine-grained facies include those of thesubaqueous lagoon and tidal flats, which are situated adjacentto the barrier or on landward side of the lagoon (Fig. 16).Organic deposits of coal and peat record marsh and swampenvironments and usually are very thin, having formed onsand and mud flats succession of the lagoonal margin84,86.Whereas, subaqueous shale and siltstone facies in lagoondeposits are often characterized by brackish water. The goodexample of worldwide lagoon and barrier is the Fire island inNew York, Texas barrier island.
STRAND PLAINS
A strand plain is a broad belt of sand along a shorelinewith surface exhibiting well defined parallel or semi-parallelsand ridges separated by shallow swales. A strand plain differsfrom a barrier in that, it lacks either lagoons or tidal marsh thatseparate a barrier from the shoreline to which the strand plainis directly attached. Also the tidal channels and inlets, whichcut through barrier islands are absent84 (Fig. 16). Strand plainstypically are created by the redistribution of waves andlongshore currents sediment on either side of a river mouth.Thus, they are part of one type of wave-dominated delta80.
Depositional environment and processes: The strand plainsare marine-process-dominated depositional features weldedinto coastal mainland’s (Fig. 16). According to Harris andHeap58, strand plains form where wave-induced sedimenttransport (littoral drift) results in the formation of a series ofcoast-parallel depositional features. These strand plains areclassed into two broad groups, beach ridges and cheniers
228
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Fig. 16: Morphological features of a coastline influenced by wave processes and tidal currents, results in strand plains and barrier
Fig. 17: Two subdivision group of strand plains due to strong wave action i.e., beach ridges and cheniersBeach ridges complex is a strike-elongate, narrow shally bodies that compose the ridges separating mud flats on chenier plains
(Fig. 17). Beach ridge and chenier plains are dominantlyprogradational features, shaped by the relations amongsediment texture and rate of supply, coastal physiography(including slope), wave and tidal energy87.
An abundant supply of mud is required for thedevelopment of chenier plains. Beach ridges complex is astrike-elongate, narrow shally bodies that compose the ridgeseparating mud flats on chenier plains53,87 (Fig. 17). Twoprocesses account for their origin. During periods of lowsediment supply, wave winnows the intertidal mud flats andconcentrate the coarser clastic and shelly detritus into
beach-ridges, forming Cheniers that rest on shoreface clays.Alternatively, storm-washover processes may build chenierson marsh deposits87.
Stratigraphy and facies characteristics: The two broadgroups of strand plains (Beach ridges and chenier plains) aredominantly progradational feature87. Beach ridges aresemi-continuous, generally mound of shelly sand and gravel,deposited above the high tide line88. A sandy beach is alwayspresent in front of the beach ridge, as marine-derivedsediment accumulates along the coast, the sequence
229
Strand plains
Coastal plain
Tidal crack
Coastal marsh
Wave action and tidal current
Ebb tide
Flood tide
Lagoon
Barrier
Strand plain
Chenier ridges
Coastal plain
Strong wave action
Washover deposits
Beach ridges
Lagoon
Barrier islands
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Fig. 18: Morphological features of tidal flats sediments from supratidal marsh (land) to subtidal (basin)
progrades seawards leaving the coarse-grained ridges“Stranded” within the fine-grained coastal plain89. Depressionand between beach ridges may be connected and form a saltflat or shallow lagoon, joined to the sea by tidal inlets thatpunctuate the seaward ridges. The facies of beach ridgesplains are: (1) A sandy beach ridge complex, which is the mostwidespread of the strand plain facies, (2) Crosscutting fluvialdeltaic complexes, which consists of upward-fining channelsandstones. Dominate channel erode through thebeach ridges and abandonment of the lesser channelscommonly results in a mud plug88 and (3) A sandy shoreface,lies seaward of and parallel to the beach plain which consistsof finest of the coarse clastic and is transitional in position andin grain size between coarser beach, dune sands and lowershoreface to shelf mud.
The cheniers plains are comprised of coarse-grainedsediment deposited as a narrow liner ridge above the level ofhigh tide but separated from the shoreline by a marsh areacomprised of fine-grained sediment90,91 (Fig. 18). As cheniersform by reworking and erosion, the cyclical erosion andprogradation of tidal flats (e.g., from succession storm eventsassociated with varying rates of sediment supply) produces aseries of parallel cheniers. Thus, grain size is a major factordifferentiating cheniers from beach ridges. However,beach ridges with wide swales infilled by fine-grainedsediment have been mistaken for cheniers and henceknowledge of the subsurface stratigraphy of the coastalsequence may be required for definitive classification in many
cases92. Due to this constrain, cheniers have not beendifferentiated from beach ridges, in strain plain in the presentstudies.
The good recent examples of strain plains are Bahiaprovince, caravelas strain plain in Brazil, West coast of Namibia,Afrikaan in Southern Africa, Eastern Texas and South-East andSouth-West coasts of Australia.
Tidal flats: Tidal flats level muddy surface bordering anestuary, alternately submerged and exposed to the air bychanging tidal level27,93. The tidal water enters and leave a tidalflat through fairly straight major channels, with minorchannels meander and migrate considerably over periods ofseveral years29,94,95. This environment (tidal flats) is one of themost varying environments than in any other shallow-marineenvironment. This is due to alternating submergence andexposer, the varying influence of fresh river water andsaline marine waters cause physical conditions(principally, temperature, salinity and acidity) to changeswidely. The tidal flats are typically vegetated salt marsh areacut by tidal cracks that act as the conduits for water flowduring the tidal cycle66,96.
Depositional environment and processes: The tidal flats aremodified by aeolian processes, when subaerially exposed atlow tide and by wave and current processes when submergedat high tide94. Flood water is derived from the lagoon anddriven onto the flats by strong and persistent winds during the
230
Supratidal marsh
Mud
Tidal channel
Mixed mud and sand
Sand
Mean high tide level
Intertidal
Subtidal
Mean low tide level
Supratidal
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Fig. 19: Stratigraphic succession of tidal flat and its environment from supratidal flat to intertidal flatCommonly encountered structures in the sands of the subtidal and lower intertidal zone includes mud-drapes forest, reactivation surface and localherring-bone cross bedding42
passage of cold fronts and tropical cyclones85,93. Low surfacegradients of the flats prevent rapid drainage and promoteseawater evaporation. The depositional products of theseprocesses are interbedded and interlaminated sand, mud,marine shells and algal mats and evaporate95. The tidal flatshave been divided into three basic environments i.e., subtidal,intertidal and supratidal (Fig. 19). The subtidal zone is belowlow tide and seldom exposed subaerially, the intertidal zonelies between normal low and high tides and is exposed onceor twice daily, whereas, supratidal zone is above high tide andsediment deposited are exposed to subaerial conditions(most of the time with flooding) only during spring or stormtides. The supratidal is the highest part of the tidal flats maybecome vegetated to produced salt marshes, where thestratification is largely destroyed by rootlets. Salt water andfreshwater peats can accumulate here. Desiccation cracksare most abundant in the upper intertidal and supratidalzones27,96.
Tidal flats along exposed, open coasts exhibit thelandward fining trend may be coarser-grained because of
wave action and contain more wave-generated structure thantidal flat96,97. In tropical climates, sea grasses and mangrovescommonly colonize large part of the tidal flats98. The muddypart of the tidal flats are dissected by a network of small-tomedium-sized meandering tidal channels that increase inwidth and depth as the coalesce seaward (Fig. 20).
Stratigraphy and facies characteristics: The tidal flatssediments are common along prograding coasts,characterized by mean tidal ranges >.4 m. They usuallycomprised of fine-grained marine sediment that has beentransported towards the coast by strong currents associatedwith the larger tides. During the falling tide, drainage ofseawater from the intertidal flats causes the development oftidal creeks96,99. Large tidal creeks often contain tidal sandbanks and dunes. The mixed flats, in which mud layersbecome more abundant as the distance from the channelincreases, lie shoreward of the sand flats. Mud flats consistingof laminated muds with relatively little sand lay still furtherlandward (Fig. 18).
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Mudstone
Sandstone
Silty sand
Coal
Parallel lamination
Bioturbation
Cross bedded trough
Herring-bone cross bedded
Flaser bedded
Hummockey cross-stratified
Wave-ripple lamination
Erosive
Mud clasts
Lithology Structures
Environment
Swamp
Supratidal flat Intertidal flat Subtidal flat Supratidal flat
Facies
Coal
Burrowed and rooted mudstone
Burrowed mudstone and trough cross laminated sandstone with flaser to lenticular bedding
Sigmoidal cross bedded sandstone
Flooding surface
Met
ers
to te
ns o
f m
eter
s
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Fig. 20(a-c): An example of landsat images of Sebkha El Melah, Tunisia, (a) 1987, (b) 2001 and (c) 2011, with cyclic episodes of tidalflat deposits that are periodically inundated with evaporation process, leaving behind salt1987: Landsat image of Sebkha El Melah, Tunisia was flooded, 2001: Landsat image of same area mostly dry, with salt deposition. Note rectangularindustrial evaporite pans, for sea-salt production, upper right (circle) and 2011: Landsat image of same area highly flooded, industrial of evaporite pans,flooded, industrial of evaporite pans, for sea-salt production increases, upper right (circle)
The tidal builds a progradational succession. Theprogradation of tidal flat generates an upward-finingsuccession67,72,93. The succession typically begins with anerosional base that is scoured by tidal channels during a localtransgression. Above this there is a gradual upward decreasein the grain size and thickness of sand beds and an increase inproportion of mud (Fig. 19). Commonly encounteredstructures in the sands of the subtidal and lower intertidalzone includes mud-drapes forest, reactivation surface andlocal herringbone cross bedding. The intertidal mud flatscontain abundant flaser and lenticular bedding and erosionalbased tidal sediments. Rooted horizons and coals occur in thesalt marsh. The bioturbation may ranges from very low toextensive. The good examples are known from the Wash, UK99
and from San Sebastian Bay, Argentina96. They are usuallycomprised of fine-grained marine sediment that has beentransported towards the coast by strong currentsassociated with the large tide58. Sabkhas are another goodexample that, although rare today is important to thegeologic past of certain regions. Sabkhas can be thought
of as tidal flats that are periodically inundated with waterevaporated and leaving behind salt (Fig. 20).
CONCLUSION
This review has confirmed that key controls onmorphology of shallow-marine clastic coastal depositionalenvironments can easily be prophesied from the influence ofwave, tide and river processes. The conceptual ternarydiagram classifying the distribution of environments areoperated by wave, tide and river power, resulting solely in7 depositional processes which are main controls in faciesstyle and architecture for erecting models. These processes arecontrolled by shoreline movements with sediment supply andaccommodation space created.
Our review designates that deltas generally initiate alongcoasts having conditions of lower wave and tide influx, thancoastlines where estuaries are predominant. This makeprobable results that higher wave and tide power results inestuaries, losing a greater percentage of sediment to the
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adjacent shelf and coastal areas. Thus inhibiting deltadevelopment with variation in the stratigraphic architectureof estuaries and creeks that drain intertidal flats and isnaturally turbid and generally well amalgamated with uniquesedimentary structures (e.g., herringbone cross beddedsandstone). In contrast, water contained in wave-dominateddeltaic, wave-dominated estuaries and lagoons are naturallyclear (low turbidity) and exhibits mainly clean stratified thickstratigraphic patterns in sedimentation with unique structures(e.g., hummocky cross-stratified sandstone). The sameapproach (using a database of coastal environments in thisreview) could be applied to any region on earth where clasticcoastal depositional environments may be identified fromstratigraphic characteristics.
ACKNOWLEDGMENTS
The technically contents and ideas presented in this studyare solely the author’s interpretations. The authors gratefullythank the reviewers for their critical and constructive reviewswhich helped in improving this study.
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